Multiple Axis Robotic Additive Manufacturing System and Methods

1. A multiple axis robotic additive manufacturing system, comprising: a robotic arm movable in six degrees of freedom; a build platform movable in at least two degrees of freedom independent of movement of the robotic arm to position a part being built on the build platform so as to counteract effects of gravity based upon a geometry of the part; an extruder mounted at an end of the robotic arm and configured to extrude material with a plurality of flow rates; a controller configured to synchronize movement of the robotic arm and the build platform with a flow rate of the material being extruded so as to print the part along a continuous 3D tool path to comprise a net or near-net, elongated hollow member having a length and a diameter following a complex curvature and having overhanging or free space segments without support structures; and a pre-heater configured to locally pre-heat a previously printed portion of the part along the 3D tool path prior to extrusion of material along the 3D tool path by the extruder to print a subsequent portion of the part on the previously printed portion of the part.

2. The multiple axis robotic additive manufacturing system of claim 1 , wherein the build platform is configured to rotate about a central axis thereof.

3. The multiple axis robotic additive manufacturing system of claim 1 , wherein the build platform is configured to tilt from substantially vertical to substantially horizontal.

4. The multiple axis robotic additive manufacturing system of claim 1 , wherein the build platform is configured to rotate about a central axis thereof and to tilt from substantially vertical to substantially horizontal.

5. The multiple axis robotic additive manufacturing system of claim 1 , wherein the robotic arm is mounted on a rail or a gantry to provide additional degrees of freedom.

6. The multiple axis robotic additive manufacturing system of claim 1 , wherein the pre-heater comprises a gas jet heater, a laser source heater, or a hybrid gas jet and laser pre-heater.

7. The multiple axis robotic additive manufacturing system of claim 1 , and further comprising a cooler configured to actively cool the extruded material along the 3D tool path.

8. The multiple axis robotic additive manufacturing system of claim 7 , wherein the cooler is a gas jet cooler.

9. The multiple axis robotic additive manufacturing system of claim 1 , and further comprising: a tool changer configured to change the extruder for another tool.

10. The multiple axis robotic additive manufacturing system of claim 9 , wherein the tool changer is configured to change the extruder for a subtractive manufacturing tool.

11. A method of printing a 3D part with a multiple axis robotic additive manufacturing system according to claim 1 , the method comprising: using the extruder to print the hollow member as a first portion of the part on the build platform by extruding a first thermoplastic material along the continuous 3D tool path as a first 3D tool path; orienting the part during the extruding by moving the build platform based on a geometry of the first portion of the part and using the controller to synchronize movement of the build platform and movement of the robotic arm with the flow rate of the material being extruded; and locally pre-heating a surface of the first portion of the part while using the extruder to extrude a second thermoplastic material along a second 3D tool path to form a second portion of the part, wherein the local pre-heating comprises pre-heating to approximately a temperature at which the second thermoplastic material will adhere to the first thermoplastic material of the first portion of the part; and wherein the second portion of the part has increased adhesion to the first portion of the part due to the pre-heating.

12. The method of claim 11 , and further comprising changing a rate of the extrusion of the extruder based on geometry of the part, a speed of the robotic arm, a speed of the build platform, or combinations thereof.

13. The method of claim 11 , wherein the first and second thermoplastic materials are different from one another.

14. The method of claim 11 , wherein the first 3D tool path is a helical tool path.

15. The method of claim 11 , wherein the first 3D tool path is a helical tool path and wherein the hollow member is a tubular member.

16. The method of claim 11 , wherein the hollow member is a tubular member and the second portion of the part comprises a fin, and wherein the second 3D tool path forms a contact edge along which the second portion of the part is printed onto the first portion of the part.

17. The method of claim 11 , wherein the second 3D tool path comprises planar tool path portions.

18. A method of out of oven 3D printing of a part using the multiple axis robotic additive manufacturing system according to claim 1 , the method comprising: using the extruder to extrude the hollow member as a first portion of the part along the continuous 3D tool path as a first 3D tool path while using the controller to synchronize movement of the robotic arm and the build platform; and using the extruder to extrude a contact edge of a second portion of the part conformally to a surface of the first portion of the part along a second 3D tool path while using the controller to synchronize movement of the robotic arm and the build platform; wherein extruding a contact edge of a second portion of the part comprises locally pre-heating a portion of the first portion of the part along the second 3D tool path prior to extruding on that portion of the first portion of the part.

19. The method of claim 18 , and further comprising actively cooling extruded material previously subjected to said pre-heating along the second tool path.

20. The method of claim 18 , wherein the material of the first portion is different from the material of the second portion.